Sunwoo Kim, Doyun Im, Yeonghun Yun, Devthade Vidyasagar, Sung Woong Yang, Won Chang Choi, Rajendra Kumar Gunasekaran, Sangheon Lee, Yong Tae Kim, Mun Young Woo, Dong Hoe Kim, Jun Hong Noh, Jaeyeong Heo, Roy Byung Kyu Chung, Sangwook Lee
{"title":"利用纳米级无机卤化物屏障稳定宽带隙包光石以实现下一代串联技术","authors":"Sunwoo Kim, Doyun Im, Yeonghun Yun, Devthade Vidyasagar, Sung Woong Yang, Won Chang Choi, Rajendra Kumar Gunasekaran, Sangheon Lee, Yong Tae Kim, Mun Young Woo, Dong Hoe Kim, Jun Hong Noh, Jaeyeong Heo, Roy Byung Kyu Chung, Sangwook Lee","doi":"10.1002/aenm.202404366","DOIUrl":null,"url":null,"abstract":"Wide-bandgap (WBG) perovskite solar cells (PSCs) play a crucial role in advancing perovskite-based tandem solar cells. In WBG perovskite films, grain boundary (GB) defects are the main contributors to open-circuit voltage (<i>V</i><sub>OC</sub>) deficits and performance degradation. This report presents an effective strategy for passivating GBs by incorporating an inorganic protective layer and reducing the density of GBs in perovskite films. This is achieved by integrating potassium thiocyanate (KSCN) into I-Br mixed halide WBG perovskites. It is reported for the first time that the incorporation of KSCN creates band-shaped barriers along the GBs. In addition, KSCN enlarges the grains of perovskite film. Elemental and structural analyses reveal that these barriers are composed of potassium lead halide. Incorporating KSCN significantly enhances the fill factor and <i>V</i><sub>OC</sub> of WBG single-junction PSCs by reducing trap density. This results in high power conversion efficiencies of 19.22% (bandgap of 1.82 eV), 20.45% (1.78 eV), and 21.54% (1.70 eV) with a C<sub>60</sub>/bathocuproine electron transport layer, and 18.51% (1.82 eV) with a C<sub>60</sub>/SnO<sub>2</sub>. Furthermore, both operational and shelf stabilities are significantly improved due to reduced light-induced halide segregation. 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This results in high power conversion efficiencies of 19.22% (bandgap of 1.82 eV), 20.45% (1.78 eV), and 21.54% (1.70 eV) with a C<sub>60</sub>/bathocuproine electron transport layer, and 18.51% (1.82 eV) with a C<sub>60</sub>/SnO<sub>2</sub>. Furthermore, both operational and shelf stabilities are significantly improved due to reduced light-induced halide segregation. 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Stabilizing Wide-Bandgap Perovskite with Nanoscale Inorganic Halide Barriers for Next-Generation Tandem Technology
Wide-bandgap (WBG) perovskite solar cells (PSCs) play a crucial role in advancing perovskite-based tandem solar cells. In WBG perovskite films, grain boundary (GB) defects are the main contributors to open-circuit voltage (VOC) deficits and performance degradation. This report presents an effective strategy for passivating GBs by incorporating an inorganic protective layer and reducing the density of GBs in perovskite films. This is achieved by integrating potassium thiocyanate (KSCN) into I-Br mixed halide WBG perovskites. It is reported for the first time that the incorporation of KSCN creates band-shaped barriers along the GBs. In addition, KSCN enlarges the grains of perovskite film. Elemental and structural analyses reveal that these barriers are composed of potassium lead halide. Incorporating KSCN significantly enhances the fill factor and VOC of WBG single-junction PSCs by reducing trap density. This results in high power conversion efficiencies of 19.22% (bandgap of 1.82 eV), 20.45% (1.78 eV), and 21.54% (1.70 eV) with a C60/bathocuproine electron transport layer, and 18.51% (1.82 eV) with a C60/SnO2. Furthermore, both operational and shelf stabilities are significantly improved due to reduced light-induced halide segregation. By using inorganic-halide-passivated WBG sub-cells, a monolithic all-perovskite tandem solar cell with an efficiency of 27.04% is demonstrated.
期刊介绍:
Established in 2011, Advanced Energy Materials is an international, interdisciplinary, English-language journal that focuses on materials used in energy harvesting, conversion, and storage. It is regarded as a top-quality journal alongside Advanced Materials, Advanced Functional Materials, and Small.
With a 2022 Impact Factor of 27.8, Advanced Energy Materials is considered a prime source for the best energy-related research. The journal covers a wide range of topics in energy-related research, including organic and inorganic photovoltaics, batteries and supercapacitors, fuel cells, hydrogen generation and storage, thermoelectrics, water splitting and photocatalysis, solar fuels and thermosolar power, magnetocalorics, and piezoelectronics.
The readership of Advanced Energy Materials includes materials scientists, chemists, physicists, and engineers in both academia and industry. The journal is indexed in various databases and collections, such as Advanced Technologies & Aerospace Database, FIZ Karlsruhe, INSPEC (IET), Science Citation Index Expanded, Technology Collection, and Web of Science, among others.